#![no_std] pub mod spi; use embedded_hal::{ blocking::{delay::DelayUs, spi::Transfer}, digital::v2::OutputPin, }; pub mod rx; pub mod tx; #[cfg(feature = "smoltcp")] pub mod smoltcp_phy; /// Max raw frame array size pub const RAW_FRAME_LENGTH_MAX: usize = 1518; /// Trait representing PHY layer of ENC424J600 pub trait EthPhy { fn recv_packet(&mut self, is_poll: bool) -> Result; fn send_packet(&mut self, packet: &tx::TxPacket) -> Result<(), Error>; } /// TODO: Improve these error types #[derive(Debug)] pub enum Error { SpiPortError, RegisterError, // TODO: Better name? NoRxPacketError, } impl From for Error { fn from(_: spi::Error) -> Error { Error::SpiPortError } } /// ENC424J600 controller in SPI mode pub struct Enc424j600, NSS: OutputPin> { spi_port: spi::SpiPort, rx_buf: rx::RxBuffer, tx_buf: tx::TxBuffer, } impl, NSS: OutputPin> Enc424j600 { pub fn new(spi: SPI, nss: NSS) -> Self { Enc424j600 { spi_port: spi::SpiPort::new(spi, nss), rx_buf: rx::RxBuffer::new(), tx_buf: tx::TxBuffer::new(), } } #[cfg(feature = "cortex-m-cpu")] pub fn cpu_freq_mhz(mut self, freq: u32) -> Self { self.spi_port = self.spi_port.cpu_freq_mhz(freq); self } pub fn init(&mut self, delay: &mut impl DelayUs) -> Result<(), Error> { self.reset(delay)?; self.init_rxbuf()?; self.init_txbuf()?; Ok(()) } pub fn reset(&mut self, delay: &mut impl DelayUs) -> Result<(), Error> { // Write 0x1234 to EUDAST self.spi_port.write_reg_16b(spi::addrs::EUDAST, 0x1234)?; // Verify that EUDAST is 0x1234 let mut eudast = self.spi_port.read_reg_16b(spi::addrs::EUDAST)?; if eudast != 0x1234 { return Err(Error::RegisterError); } // Poll CLKRDY (ESTAT<12>) to check if it is set loop { let estat = self.spi_port.read_reg_16b(spi::addrs::ESTAT)?; if estat & 0x1000 == 0x1000 { break; } } // Issue system reset - set ETHRST (ECON2<4>) to 1 self.spi_port.send_opcode(spi::opcodes::SETETHRST)?; delay.delay_us(25); // Verify that EUDAST is 0x0000 eudast = self.spi_port.read_reg_16b(spi::addrs::EUDAST)?; if eudast != 0x0000 { return Err(Error::RegisterError); } delay.delay_us(256); Ok(()) } pub fn init_rxbuf(&mut self) -> Result<(), Error> { // Set ERXST pointer self.spi_port .write_reg_16b(spi::addrs::ERXST, self.rx_buf.get_start_addr())?; // Set ERXTAIL pointer self.spi_port .write_reg_16b(spi::addrs::ERXTAIL, self.rx_buf.get_tail_addr())?; // Set MAMXFL to maximum number of bytes in each accepted packet self.spi_port .write_reg_16b(spi::addrs::MAMXFL, RAW_FRAME_LENGTH_MAX as u16)?; // Enable RX - set RXEN (ECON1<0>) to 1 self.spi_port.send_opcode(spi::opcodes::ENABLERX)?; Ok(()) } pub fn init_txbuf(&mut self) -> Result<(), Error> { // Set EGPWRPT pointer self.spi_port.write_reg_16b(spi::addrs::EGPWRPT, 0x0000)?; Ok(()) } /// Set controller to Promiscuous Mode pub fn set_promiscuous(&mut self) -> Result<(), Error> { // From Section 10.12, ENC424J600 Data Sheet: // "To accept all incoming frames regardless of content (Promiscuous mode), // set the CRCEN, RUNTEN, UCEN, NOTMEEN and MCEN bits." let erxfcon_lo = self.spi_port.read_reg_8b(spi::addrs::ERXFCON)?; self.spi_port.write_reg_8b( spi::addrs::ERXFCON, 0b0101_1110 | (erxfcon_lo & 0b1010_0001), )?; Ok(()) } /// Read MAC to [u8; 6] pub fn read_mac_addr(&mut self, mac: &mut [u8]) -> Result<(), Error> { mac[0] = self.spi_port.read_reg_8b(spi::addrs::MAADR1)?; mac[1] = self.spi_port.read_reg_8b(spi::addrs::MAADR1 + 1)?; mac[2] = self.spi_port.read_reg_8b(spi::addrs::MAADR2)?; mac[3] = self.spi_port.read_reg_8b(spi::addrs::MAADR2 + 1)?; mac[4] = self.spi_port.read_reg_8b(spi::addrs::MAADR3)?; mac[5] = self.spi_port.read_reg_8b(spi::addrs::MAADR3 + 1)?; Ok(()) } pub fn write_mac_addr(&mut self, mac: &[u8]) -> Result<(), Error> { self.spi_port.write_reg_8b(spi::addrs::MAADR1, mac[0])?; self.spi_port.write_reg_8b(spi::addrs::MAADR1 + 1, mac[1])?; self.spi_port.write_reg_8b(spi::addrs::MAADR2, mac[2])?; self.spi_port.write_reg_8b(spi::addrs::MAADR2 + 1, mac[3])?; self.spi_port.write_reg_8b(spi::addrs::MAADR3, mac[4])?; self.spi_port.write_reg_8b(spi::addrs::MAADR3 + 1, mac[5])?; Ok(()) } } impl, NSS: OutputPin> EthPhy for Enc424j600 { /// Receive the next packet and return it /// Set is_poll to true for returning until PKTIF is set; /// Set is_poll to false for returning Err when PKTIF is not set fn recv_packet(&mut self, is_poll: bool) -> Result { // Poll PKTIF (EIR<4>) to check if it is set loop { let eir = self.spi_port.read_reg_16b(spi::addrs::EIR)?; if eir & 0x40 == 0x40 { break; } if !is_poll { return Err(Error::NoRxPacketError); } } // Set ERXRDPT pointer to next_addr self.spi_port .write_reg_16b(spi::addrs::ERXRDPT, self.rx_buf.get_next_addr())?; // Read 2 bytes to update next_addr let mut next_addr_buf = [0; 3]; self.spi_port.read_rxdat(&mut next_addr_buf, 2)?; self.rx_buf .set_next_addr((next_addr_buf[1] as u16) | ((next_addr_buf[2] as u16) << 8)); // Read 6 bytes to update rsv let mut rsv_buf = [0; 7]; self.spi_port.read_rxdat(&mut rsv_buf, 6)?; // Construct an RxPacket // TODO: can we directly assign to fields instead of using functions? let mut rx_packet = rx::RxPacket::new(); // Get and update frame length rx_packet.write_to_rsv(&rsv_buf[1..]); rx_packet.update_frame_length(); // Read frame bytes let mut frame_buf = [0; RAW_FRAME_LENGTH_MAX]; self.spi_port .read_rxdat(&mut frame_buf, rx_packet.get_frame_length())?; rx_packet.copy_frame_from(&frame_buf[1..]); // Set ERXTAIL pointer to (next_addr - 2) // * Assume head, tail, next and wrap addresses are word-aligned (even) // - If next_addr is at least (start_addr+2), then set tail pointer to the word right before next_addr if self.rx_buf.get_next_addr() > self.rx_buf.get_start_addr() { self.spi_port .write_reg_16b(spi::addrs::ERXTAIL, self.rx_buf.get_next_addr() - 2)?; // - Otherwise, next_addr will wrap, so set tail pointer to the last word address of RX buffer } else { self.spi_port .write_reg_16b(spi::addrs::ERXTAIL, rx::RX_MAX_ADDRESS - 1)?; } // Decrement PKTCNT - set PKTDEC (ECON1<8>) self.spi_port.send_opcode(spi::opcodes::SETPKTDEC)?; // Return the RxPacket Ok(rx_packet) } /// Send an established packet fn send_packet(&mut self, packet: &tx::TxPacket) -> Result<(), Error> { // Set EGPWRPT pointer to next_addr self.spi_port .write_reg_16b(spi::addrs::EGPWRPT, self.tx_buf.get_next_addr())?; // Copy packet data to SRAM Buffer // 1-byte Opcode is included let mut txdat_buf: [u8; RAW_FRAME_LENGTH_MAX + 1] = [0; RAW_FRAME_LENGTH_MAX + 1]; packet.write_frame_to(&mut txdat_buf[1..]); self.spi_port .write_txdat(&mut txdat_buf, packet.get_frame_length())?; // Set ETXST to packet start address self.spi_port .write_reg_16b(spi::addrs::ETXST, self.tx_buf.get_next_addr())?; // Set ETXLEN to packet length self.spi_port .write_reg_16b(spi::addrs::ETXLEN, packet.get_frame_length() as u16)?; // Send packet - set TXRTS (ECON1<1>) to start transmission self.spi_port.send_opcode(spi::opcodes::SETTXRTS)?; // Poll TXRTS (ECON1<1>) to check if it is reset loop { let econ1_lo = self.spi_port.read_reg_8b(spi::addrs::ECON1)?; if econ1_lo & 0x02 == 0 { break; } } // TODO: Read ETXSTAT to understand Ethernet transmission status // (See: Register 9-2, ENC424J600 Data Sheet) // Update TX buffer start address // * Assume TX buffer consumes the entire general-purpose SRAM block self.tx_buf.set_next_addr( (self.tx_buf.get_next_addr() + packet.get_frame_length() as u16) % self.rx_buf.get_start_addr() - self.tx_buf.get_start_addr(), ); Ok(()) } }